Method and Tools for Installation a Transmission Shift Cable End Bushing

ABSTRACT

Installation of a bushing into the shift cable end of an automatic transmission, without replacing the entire shift cable end, is accomplished via methods and specialized tools that do not require the use of compression tools, or divert the force applied by compressive tools away from the non-load-bearing surfaces of the bushing and shift cable end, and maintain the axial alignment of the bushing with the shift cable end during installation, thus preventing deformation of the shift cable end and bushing during installation, and ensuring the proper coupling of the shift cable end and shift lever. In particular embodiments, a shift cable end protective member is secured to the shift cable end, a bushing installation member is inserted into the bushing, through the shift cable end and into the protective member, and a compressive force is applied simultaneously to the protective member and installation member, thus pressing the bushing into place within the shift cable end. The protective member and installation member work in tandem to divert the compressive force away from the shift cable end, average the compressive force across the bushing, and maintain the alignment of the bushing with the shift cable end as the bushing is pressed into the shift cable end. In other embodiments, the bushing may be installed by hand without the use of a compression tool by utilizing an installation member carrying a compression cavity that allows for the compression of the bushing by hand. The installation member is passed through the shift cable end and removed, allowing the bushing to expand into place within the shift cable end.

CROSS-REFERENCES TO RELATED APPLICATIONS

Not Applicable.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH

Not Applicable.

NAMES OF PARTIES TO JOINT RESEARCH AGREEMENT

Not Applicable

REFERENCE TO A SEQUENCE LISTING

Not Applicable.

BACKGROUND OF THE INVENTION

(1) Field of Invention

The present invention relates generally to special purpose tools, and more particularly, to bushing tools, and methods of use, for installation of a bushing into the end of a transmission shift control linkage of various motor vehicles without damaging the shift cable end or the bushing.

The transmission shift control linkage of many motor vehicles generally consists of a shift cable that connects the gear selector or shift lever to the motor vehicle's transmission. The shift cable end is coupled with the gear selector or shift lever via a bushing that allows for the smooth operation of the shift linkage. The bushing installed in the shift cable end of various motor vehicles consists of plastic that dries, rots and becomes brittle over time. The degradation or failure of the bushing allows the shift cable end to become decoupled from the gear selector or shift lever, making it impossible for the operator of the automobile to engage and shift the transmission.

Presently, the failure of a transmission shift cable end bushing in various motor vehicles requires the removal and replacement of the entire shift cable. This is because the replacement of factory-installed bushings by mechanics generally involve the application of conventional or makeshift tools that deform or otherwise damage the shift cable end or bushing during installation and fail to properly align the bushing with the shift cable end during installation. This results in a sub-standard repair that may not properly couple the shift cable end with the shift lever. Also, degraded factory-installed bushings are occasionally replaced with non-factory, “universal” bushings. Such bushings are not necessarily intended or tailored for any specific application and, when installed, often fail to properly engage the shift cable end, resulting in a sub-standard repair that may not properly couple the shift cable end with the shift lever. Additionally, the supply and labor costs associated with the replacement of the entire shift cable assembly are substantially greater than the supply and labor costs associated with the replacement of the shift cable bushing.

(2) Background Art

There are several bushing installation tools and methods for installing bushings into various housings, including machine housings associated with the internal components of an automatic transmission. An example of such a tool is shown in U.S. Pat. App. No. US2008/0066281, which discloses a pair of linkage bushing installation pliers that operates by coaxially forcing a linkage bushing into the receiving aperture of a machine housing. While such devices fulfill their particular purposes, the application of such tools to the problem of installing a shift cable end bushing without replacing the entire shift cable assembly is akin to using conventional or makeshift tools, which may deform or damage the shift cable end or bushing, resulting in a sub-standard repair that may not properly couple the shift cable end with the shift lever. Such tools are not equipped with a means of diverting compressive forces away from the shift cable end or averaging the force across a shift cable end bushing during installation. Moreover, the present invention is more easily and inexpensively manufactured.

SUMMARY OF THE INVENTION

Accordingly, it is the object of the present invention to provide specialized tools and methods of use for the prompt installation of a factory bushing or the equivalent into the transmission shift cable end that does not damage the shift cable end or the bushing, maintains the alignment of the bushing with the shift cable end during the installation, ensures the proper coupling of the shift cable end and shift lever, and avoids the need of replacing the entire shift cable.

In accordance with the invention, the proper installation of a transmission shift cable end bushing is achieved by methods utilizing specialized tools that allow for the prompt installation of the bushing by hand or that divert the force applied from compression tools during installation to the load-bearing surface of the shift cable end, average an applied compressive force across the bushing, and ensure the axial alignment of the bushing with the shift cable end throughout the installation.

In particular embodiments of the invention, the object of the invention may be accomplished by securing a shift cable end protective tool onto one side of the shift cable end, inserting a bushing installation tool into the bushing, guiding the installation tool through the shift cable end and into the protective tool, simultaneously applying a force to the outer surfaces of the protective tool and installation tool, and removing the protective and installation tools, thereby securing the bushing in the shift cable end bushing housing.

Such an installation tool may, for example, be comprised of a cylindrical member including a series of elongated and concentric members of decreasing diameter extending perpendicularly from its center which engages the bushing, diverts the force applied by a compression tool away from the inner annular surface of the bushing and averages such a force across the trailing shoulder of the bushing, and engages the protective tool to maintain the axial alignment of the bushing during installation.

The protective tool may be comprised of a cylindrical member with a securing means, or annular surface extending perpendicularly around its circumference for securing onto the shift cable end, a force-diverting means or cavity for housing the fragile members of the shift cable end and allowing the cylindrical member to contact the load-bearing, flat annular surface of the shift cable end, and an alignment means, or sleeve extending perpendicularly from the center of the cavity to allow for the axial alignment of the installation tool with the shift cable end. The securing means may carry a gripping means for gripping onto the connecting member that connects the shift cable end to the shift cable. Additionally, alignment sleeve may carry a conical guiding surface for guiding the installation tool into the sleeve during installation.

The protective tool and installation tool can be composed of any metal, polymer or copolymer capable of withstanding the physical force applied by a compression tool, such as, for example, acrylonitrile-butadiene-styrene.

If desired, particular embodiments of the invention may allow for the installation of the bushing into the shift cable end without the assistance of a compression tool. Indeed, the installation may be accomplished by hand. The bushing can be pressed into the cavity of an installation tool, radially compressing the leading shoulder of the bushing, and the installation tool can be inserted into the shift cable end receiving aperture and removed, allowing the leading shoulder of the bushing to radially expand around the inner annular surface of the receiving aperture, thereby axially aligning and securing the bushing in the shift cable end.

Such an installation tool, for example, could comprise a cylindrical member including a cavity for receiving and radially compressing the leading shoulder of a bushing. The outer diameter of the installation tool can be of a diameter that is less than the inner diameter of the shift cable end bushing housing, thereby ensuring that the leading shoulder of the bushing is radially compressed to fit through the shift cable end housing. An elongated member may be made to extend perpendicularly from the leading surface of the cylindrical member to allow for the tool to be removed from the shift cable end. The installation tool can be composed of any metal or polymer capable of supporting the invention, such as polypropylene.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective illustration showing the details of an exemplary shift cable end.

FIG. 2 is a is a perspective illustration showing the details of the bottom of the shift cable end of FIG. 1.

FIG. 3 a is a perspective side view of an exemplary bushing installed in the shift cable end of FIG. 1.

FIG. 3 b is a perspective bottom view of the bushing in FIG. 3 a.

FIG. 4 is an exploded perspective illustration of an exemplary method and tools, according to the present invention, for installing the bushing in FIG. 3 a into the shift cable end of FIG. 1.

FIG. 5 a is a perspective illustration of an exemplary shift cable end protective tool for use in installing the bushing in FIG. 3 a into the shift cable end of FIG. 1.

FIG. 5 b is a perspective illustration of the bottom of the shift cable end protective tool of FIG. 5 a.

FIG. 6 is a perspective illustration of an exemplary bushing installation tool for use in installing the bushing in FIG. 3 a into the shift cable end of FIG. 1.

FIG. 7 a is a perspective exploded view of an exemplary system and tool, according to the present invention, for installing a bushing into a shift cable end.

FIG. 7 b is a perspective view of the exemplary method and tool, according to the present invention, for installing a bushing into a shift cable end.

FIG. 8 a is a perspective illustration of an exemplary bushing for use with the method and tool of FIG. 7 a.

FIG. 8 b is a perspective illustration of an exemplary bushing for use with the method and tool of FIG. 7 a.

FIG. 9 a is a perspective illustration of an exemplary bushing installation tool for installing the bushing of FIG. 8 into the shift cable end of FIG. 7 a.

FIG. 9 b is a side elevation illustration of an exemplary bushing installation tool for installing the bushing of FIG. 8 into the shift cable end of FIG. 7 a.

DETAILED DESCRIPTION

The degradation of a factory-installed bushing or the equivalent in the shift cable end of various motor vehicles requires the replacement of the entire shift cable, wherein the new shift cable is pre-fitted with a factory bushing or the equivalent. The replacement of the entire shift cable as a means of installing a shift cable bushing is the generally accepted method because there is no known method or system for the installation of a factory bushing or the equivalent that ensures the proper coupling of the shift cable and shift lever, maintains the alignment of the bushing with the shift cable end during installation, and prevents the shift cable end and bushing from being damaged during installation.

As noted above, it remained for the present inventor to recognize that devising a method and specialized tools for the installation of a factory bushing or the equivalent into a transmission shift cable end would provide a number of benefits, including lower supply and labor costs. The present inventor further recognized that the proper installation of a shift cable end factory bushing or the equivalent in various motor vehicles could be achieved by developing methods and specialized tools that do not require the application of compression tools, or divert the force applied from compression tools away from the non-load-bearing members of the bushing and shift cable end, while simultaneously ensuring the axial alignment of the bushing with the shift cable end and the proper coupling of the shift cable and shift lever or gear selector.

Referring to FIGS. 1 and 2, an exemplary transmission shift cable end 11 for a motor vehicle (not shown) is illustrated. The shift cable end 11 operably couples the shift lever (not shown) with the shift cable (not shown) and allows the shift lever to engage the transmission (not shown). This particular example of a shift cable end 11 includes a connecting member 12 that connects the shift cable to the shift cable end 11, and a coupling aperture 13 extending through the shift cable end 11 and adapted to couple with the coupling member (not shown) of the shift lever. The coupling aperture 13 carries a mounting aperture 14 that secures a bushing by compression fit. The shift cable end 11 (FIG. 2) further includes a semi-spherical member 21 extending longitudinally from the rear surface 22 of the shift cable end 11 and a concentric aperture 23 forming a spherical cap on the semi-spherical member 21.

In this example (FIG. 3), the bushing 31 includes a sleeve 32 with shoulders extending radially from both ends. The trailing shoulder 33 engages the mounting aperture while the leading shoulder 33 extends through and beyond the mounting aperture 14 to hold the bushing 31 in place. When installed, the leading shoulder 34 of the bushing 31 is housed within the semi-spherical member 21 of the shift cable end 11. The bushing sleeve 32 carries an inner annular member 35 that engages the coupling member of the shift lever or gear lever. The shift cable end 11 and shift lever or gear lever are coupled by inserting the coupling member of the shift lever or gear lever into the coupling aperture 13 and through the bushing 31.

In accordance with the present invention, FIG. 4 illustrates an example of a method to divert the force applied from a compression tool, such as pliers, away from the non-load-bearing members of the shift cable end 11, while simultaneously ensuring the axial alignment of the bushing 31 with the shift cable end 11 and the proper coupling of the shift cable end and shift lever. In this particular method (FIG. 4), a protective means, embodied here as a shift cable end protective tool 41 is secured onto the shift cable end 11. A force-averaging means, embodied here as a bushing installation tool 42, is inserted into the bushing 31, and the bushing installation tool 42 is guided through the shift cable end 11 and into the shift cable end protective tool 41. A compressive force is then applied simultaneously to the shift cable end protective tool 41 and the bushing installation tool 42 with an appropriate compressive tool (not shown), such as pliers, until the leading shoulder 34 of the bushing 31 is inserted through and beyond the mounting aperture 14. The shift cable end protective tool 41 and bushing installation tool 42 are then removed, leaving the bushing 31 installed in the shift cable end 11.

An example of a shift cable end protective tool 41 is illustrated in FIG. 5 a and FIG. 5 b. The shift cable end protective tool 41 is comprised of a cylindrical seating member 51 including a securing means 52 for securing onto the shift cable end 11, said securing means 52 comprising an outer cylindrical peripheral surface 53 extending longitudinally from the cylindrical member 51, the cylindrical peripheral surface 53 including a gripping means for grasping and securing onto the shift cable end 11. In this particular embodiment, the gripping means is comprised of a semi-circular opening 54 of a diameter marginally greater than the diameter of the shift cable end connecting member 12, such that the semi-circular opening 54 within the cylindrical peripheral surface 53 grasps the outer surface of the shift cable end connecting member 12, and secures the shift cable end protective tool 41 to the shift cable end 11 during installation.

This particular embodiment of a shift cable end protective tool 41 further includes a means for diverting the force applied by a compression tool, such as pliers, away from the semi-spherical member 21 of the shift cable end 11, and to the rear surface 22 of the shift cable end 11, said force-diverting means comprising an annular cavity 55 with a diameter slightly greater than the diameter of the semi-spherical member 21 and a depth slightly greater than the distance between the rear surface 22 of the shift cable end 11 and the concentric aperture 23 of the semi-spherical member 21, whereby the shift cable end protective tool 41 does not make contact with the semi-spherical member 21 during installation of the bushing 31. A compressive force applied to the shift cable end protective tool 41 is thereby diverted to the rear surface 22 of the shift cable end 11.

This example of a shift cable end protective tool further includes an alignment means to ensure the alignment of the bushing 31 with the shift cable end 11 during installation, said alignment means comprising an alignment sleeve 56 centered longitudinally within the annular cavity 55, wherein the bushing installation tool 42 is inserted during installation, thereby aligning the bushing 31 within the shift cable end 11. The alignment sleeve 56 includes a conical guiding surface 57 that guides the bushing installation tool 42 into the alignment sleeve 56 during installation.

An exemplary illustration of a force-averaging bushing installation tool is provided in FIG. 6. Such an installation tool is comprised of a cylindrical bushing seating member 61 that engages the trailing shoulder 33 of the bushing 31, and carries a series of alignment means, illustrated here as concentric members of decreasing diameter extending perpendicularly from its center. This particular installation tool comprises three such members. The first is an outer alignment member 62 of a diameter slightly less than the diameter of the bushing sleeve 32 such that the outer alignment member 62 engages the bushing sleeve 32 and maintains the alignment of the bushing sleeve 32 with the bushing installation tool 42 during installation. The outer alignment member 62 extends from the cylindrical member 61 and is of a length slightly less than the distance between the inner annular member 35 of the bushing 31 and the trailing shoulder 33 of the bushing 31, thereby preventing the bushing installation tool 42 from contacting the non-load-bearing inner annular member 35 of the bushing 31 during installation. As a compressive force is applied to the bushing installation tool 42 and shift cable end protective tool 41, the combination of cylindrical member 61 and the outer alignment member 62 diverts the force away from the bushing sleeve 32 and inner annular member 35 and onto the trailing shoulder 33 of the bushing 31.

The second member is an inner alignment member 63 that maintains the alignment of the inner annular member 35 and leading shoulder 34 of the bushing 31 with the bushing installation tool 42 during installation. The inner alignment member 63 is of a diameter less than the diameter of the inner annular member 35 and extends from the leading surface 64 of the outer alignment member 62 to the leading edge of the inner annular member 35, thereby aligning the bushing 31 with the bushing installation tool 42 during installation. The third member is a bushing installation tool alignment member 65 that maintains the axial alignment of the bushing installation tool 42 with the shift cable end protective tool 41 and shift cable end 11 during installation. The bushing installation tool alignment member 65 is inserted into the alignment sleeve 56 of the shift cable end protective tool 41, thereby maintaining the alignment of the bushing installation tool 42, and thus the bushing 31, with the shift cable end protective tool 41 and shift cable end 11 as a compressive force is applied to press the leading shoulder 34 of the bushing 31 through the mounting aperture 14 and into the semi-spherical member 21.

A system comprising both a shift cable end protective tool and a bushing installation tool may be made of any metal, polymer, copolymer or other material capable of being molded for the particular application and capable of withstanding the physical force applied by a compression tool, such as pliers. The shift cable end protective tool 41 and bushing installation tool 42 of the illustrative embodiment are made of acrylonitrile-butadiene-styrene.

As noted above, the present invention may be accomplished without the use of a compressive tool, and indeed may be accomplished by hand. In accordance with this advantageous feature of the invention, and as can be seen in FIG. 7A and FIG. 7B, a bushing 72 is pressed into the cavity of a bushing installation tool 73, and the bushing installation tool 73 is inserted into and pulled through the shift cable end 71, thereby securing the bushing within the shift cable end 71. In this illustration, the shift cable end 71 similarly includes a coupling aperture 74 that extends through the shift cable end 71 and carries a mounting aperture 75 around which the bushing 72 is secured by a compression fit.

As illustrated in FIG. 8A and FIG. 8B, the bushing 72 includes a sleeve 81 with shoulders of equal diameter extending radially from both ends. The trailing shoulder 82 engages the mounting aperture 75 while the leading shoulder 93 extends through and beyond the mounting aperture 75 to hold the bushing 72 in place. However, it remained for the present inventor to recognize that making the leading shoulder 83 of the bushing 72 more compressible would allow for the leading shoulder 83 to be fitted through and beyond the mounting aperture 75 without the use of a compressive tool. Thus, the leading shoulder 83 of the bushing 72 includes a fitting mechanism that allows the leading shoulder 83 of the bushing 72 to be compressed to extend through and beyond the mounting aperture 75 with a force less than the force applied by a compression tool, such as pliers.

In this particular embodiment, the fitting mechanism is comprised of several compression notches 84 spaced evenly around the periphery of the leading shoulder 83. The compression notches 84 in this illustration are triangular cavities that collapse inward as the leading shoulder 83 of the bushing 72 is pressed through and beyond the mounting aperture 75, thereby allowing the leading shoulder 83 to be compressed and the bushing 72 installed without the use of a compressive tool. This particular embodiment includes four compression notches 84 spaced quarterly around the leading shoulder 83 of the bushing 72.

A fitting mechanism embodying the principles of the invention can have any desired number of compression notches. For example, if a fitting mechanism is comprised of six compression notches, it is guaranteed to make the leading shoulder of the bushing more compressible. However, the structural strength of a leading shoulder with six compression notches may become an issue. Similarly, a fitting mechanism may be comprised of less than four compression notches. However, a fitting mechanism comprised of less than four compression notches may not achieve the desired compressibility of the leading shoulder.

An example of a bushing installation tool utilized in tandem with such a bushing is illustrated in FIG. 9. The bushing installation tool 73, as illustrated, includes an alignment means, illustrated here as a cylindrical alignment member 91 with a diameter slightly less than the inner diameter of the mounting aperture 75, thereby allowing the bushing installation tool 73 to be inserted and passed through the shift cable end 71. The cylindrical alignment member 91 includes a compression means, illustrated here as a compression cavity 92 carried in the trailing end 93 of the cylindrical member 91 for radially compressing the leading shoulder 83 of the bushing 72 without the use of a compression tool, such as pliers, or by hand. The compression cavity 92 is of a depth equal to the length of longitudinal edge of the leading shoulder 83 of the bushing 72.

The cylindrical alignment member further carries a removal means for removing the bushing installation tool 73 through the shift cable end 71. The removal means is illustrated here as an elongated member 94 extending perpendicularly from the leading surface 95 of the cylindrical alignment member 91. The elongated member 94 carries a gripping means for gripping the bushing installation tool 73 as it is passed through the shift cable end 71, said gripping means generally comprising an indentation 95 on opposing sides of the elongated member 94.

As noted above, in this particular embodiment of the invention (FIG. 7), the leading shoulder 93 is pressed into the compression cavity 92 of the bushing installation tool 73, radially compressing the leading shoulder 83 of the bushing 72, and thereby allowing the leading shoulder 83 of the bushing 72 to pass through the mounting aperture 75. Once the bushing 72 is pressed into the compression cavity 92, the bushing installation tool 73 is pressed into the shift cable end 71, such that the elongated member passes through the mounting aperture. 75. The bushing installation tool 73 is then pulled through the shift cable end 71 by engaging and pulling on the elongated member 94. As the bushing installation tool 73 is pulled through the shift cable end 71, the trailing shoulder 82 of the bushing 72 engages the mounting aperture 75, and the leading shoulder 83 passes through and beyond the mounting aperture 75 and radially expands to secure the bushing 72 within the shift cable end 71.

A system for installing a shift cable end bushing that does not require the use of a compressive tool may be made of any metal, polymer, copolymer or other material capable of being molded for the particular application. The bushing installation tool illustrated in this particular embodiment is made of polypropylene. Similarly, a bushing having a fitting mechanism may be made of any polymer or copolymer capable of being molded for the particular application and maintaining the structural integrity of the bushing as the leading shoulder is compressed, such as polyurethane.

The foregoing merely describes the present invention in an illustrative manner. The terminology employed is intended to be merely words of description, and not of limitation. It will thus be appreciated that that those skilled in the art will be able to make numerous modification and variations of the present invention in light of the above teachings. Such modifications and variations, while not illustrated or described herein, embody the principles of the present invention, and are within the spirit and scope of the appended claims. 

1. An apparatus for installation of a bushing into the shift cable end of an automatic transmission, said shift cable end having a coupling aperture extending through the shift cable end for coupling with the transmission shift lever, said coupling aperture carrying a mounting aperture, said bushing having a sleeve carrying a leading and trailing shoulder, said apparatus comprising: a force-diverting means for diverting a compressive force away from the coupling aperture; a force-averaging means attached to said force-diverting means for averaging a compressive force across the bushing; and an alignment means attached to said force-diverting and force-averaging means for axially aligning the bushing with the coupling aperture and mounting aperture.
 2. A transmission shift cable end bushing installation tool for installation of a bushing into a transmission shift cable end, said shift cable end having a coupling aperture extending through the shift cable end for coupling with the transmission shift lever or gear lever, said coupling aperture carrying a mounting aperture, said bushing having a sleeve carrying a leading and trailing shoulder for engaging each side of the mounting aperture, said bushing installation tool comprising: an alignment means for aligning the bushing with the shift cable end coupling aperture and mounting aperture during installation, said alignment means comprising an alignment member having a first side and a second side, and sized to fit through the shift cable end mounting aperture; a compression means for compressing the leading shoulder of the bushing to fit through and beyond the shift cable end mounting aperture, said compression means housed within the first side of said alignment member; a removal means for removing the bushing installation tool from the shift cable end after the leading shoulder of the bushing has passed through and beyond the mounting aperture, thereby allowing the leading shoulder of the bushing to expand and engage the mounting aperture, said removal means attached to the second side of the alignment member;
 3. A transmission shift cable end bushing installation tool as in claim 2, wherein the alignment member is a cylindrical member of a diameter less than the diameter of the shift cable end mounting aperture.
 4. A transmission shift cable end bushing installation tool as in claim 2, wherein the bushing compression means comprises a cylindrical cavity in the first side of the alignment member of a depth greater than the longitudinal length of the leading shoulder of the bushing, wherein the leading shoulder of the bushing is pressed into the cylindrical cavity and radially compressed to a diameter less than the diameter of the mounting aperture, thereby allowing the bushing to pass through and beyond the shift cable end mounting aperture.
 5. A transmission shift cable end bushing installation tool as in claim 2, wherein the removal means is comprised of an elongated member extending perpendicularly from the second side of the alignment member, said elongated member including a gripping means for gripping and pulling on the elongated member, thereby removing the alignment member from the shift cable end coupling aperture.
 6. A transmission shift cable end bushing installation tool as in claim 2, wherein the bushing installation tool is made of polypropylene.
 7. A transmission shift cable end bushing installation tool as in claim 5, wherein the gripping means is comprised of indentations on opposing sides of the elongated member.
 8. A method for installing a bushing into a transmission shift cable end, said shift cable end having a coupling aperture extending through the shift cable end for coupling with the shift lever or gear lever, said coupling aperture carrying a mounting aperture, said bushing having a sleeve carrying a leading and trailing shoulder for engaging each side of the mounting aperture, said method comprising: pressing the leading shoulder of the bushing into a bushing installation tool by hand, wherein the leading shoulder of the bushing is compressed, thereby allowing it to pass through the mounting aperture; inserting said bushing installation tool into the shift cable end coupling aperture, wherein the leading shoulder of the bushing extends through and beyond the mounting aperture and the trailing shoulder of the bushing engages the mounting aperture; pulling said bushing installation tool from the shift cable end coupling aperture, thereby releasing the leading shoulder of the bushing so that it expands to engage the mounting aperture and secures the bushing in the shift cable end.
 9. A method as in claim 8, comprising using a bushing installation tool having a cylindrical member with a first side and a second side and a diameter less than the diameter of the mounting aperture, a bushing compression means within the first side of the cylindrical member, said bushing compressing means comprising a cylindrical cavity of a depth equal to the longitudinal length of the leading shoulder of the bushing, and a pulling means attached to the second side of the cylindrical member, said pulling means comprising an elongated member extending perpendicularly from the second side of said cylindrical member, said elongated member carrying a gripping means; pressing the leading shoulder of the bushing into the compression means of the bushing installation tool; inserting the bushing installation tool into the shift cable end coupling aperture such that the pulling means is inserted first, followed by the cylindrical member, wherein the leading shoulder of the bushing extends through and beyond the mounting aperture and the trailing shoulder of the bushing engages the mounting aperture; pulling said bushing installation tool from the shift cable end coupling aperture by engaging the pulling means, thereby removing the compression means from the leading shoulder of the bushing and allowing the leading shoulder of the bushing to radially expand to engage the mounting aperture and secure the bushing within the shift cable end.
 10. A method as in claim 8 comprising using a bushing that is more compressible than the original bushing, said bushing having a fitting mechanism in the leading shoulder of the bushing, thereby allowing the bushing to be pressed into the bushing installation tool and installed more readily without the use of a compression tool.
 11. A method as in claim 8 comprising using a bushing having a fitting mechanism comprised of several compression notches spaced evenly around the leading shoulder of the bushing, whereby the compression notches collapse inward as the leading shoulder of the bushing is pressed into the bushing installation tool and installed.
 12. A method as in claim 8 comprising using a bushing having a fitting mechanism comprised of four triangular compression notches spaced evenly around the leading shoulder of the bushing, wherein the triangular compression notches collapse as the leading shoulder of the bushing is pressed into the bushing installation tool and installed.
 13. A method as in claim 9 comprising using a bushing installation tool made of polypropylene.
 14. A method as in claim 10 wherein the bushing is made of polyurethane.
 15. An apparatus for installation of a bushing into a shift cable end, said shift cable end having a connecting member that connects the shift cable end to the shift cable, a coupling aperture extending through the shift cable end for coupling with the shift lever or gear lever, a semi-spherical member extending longitudinally from its rear surface, said semi-spherical member including a concentric aperture forming a spherical cap, a mounting aperture carried in the coupling aperture, said mounting aperture having a first sidewall and a second sidewall, said bushing having a sleeve dimensioned to fit inside the mounting aperture carrying an inner annular member and having a leading and trailing shoulder for engaging each sidewall of the mounting aperture, comprising: a shift cable end protective means for diverting a compressive force away from the semi-spherical member of the bushing to the rear surface of the bushing; a force-averaging means for averaging a compressive force across the trailing shoulder of the bushing; wherein the shift cable end protective means is engaged by the force-averaging means to maintain the axial alignment of the bushing with the longitudinal axis of the shift cable end coupling aperture.
 16. An apparatus as in claim 15 wherein said shift cable end protective means comprises a shift cable end seating member having a first side and a second side, said shift cable end seating member having a securing means attached to its first side for securing on to one end of the shift cable end, a gripping means for gripping onto the shift cable end connecting member, a force-diverting means for diverting a compressive force away from the semi-spherical member and to the rear surface of the shift cable end, said force-diverting means comprising a cavity within the first side of the seating member, said cavity sized to house the semi-spherical member, and an alignment means, said alignment means comprising an alignment sleeve centered around the longitudinal axis of the cavity within the first side of the seating member, said alignment sleeve extending to the second side of the seating member, said alignment sleeve carrying a guiding surface for guiding a bushing installation member into the alignment sleeve.
 17. An apparatus as in claim 15 wherein said shift cable end protective means is comprised of a cylindrical member having a first side and a second side, a peripheral annular surface of diameter greater than the outer diameter of the shift cable end extending longitudinally from the first side of the cylindrical member, said peripheral annular surface carrying a semi-circular opening of diameter marginally greater than the diameter of the shift cable end connecting member, an annular cavity in the first side of the cylindrical member, said annular cavity of a diameter greater than the diameter of the semi-spherical member and a height greater than the distance between the rear surface of the shift cable end and the spherical cap of the semi-spherical member, a cylindrical alignment sleeve centered around the longitudinal axis of the annular cavity, said alignment sleeve having an inner diameter sized to fit the second alignment means of the bushing installation member and carrying a conical guiding surface extending radially outward from the inner diameter to the outer diameter of the alignment sleeve.
 18. An apparatus as in claim 15 where in said force averaging means is comprised of a bushing installation member, said bushing installation member having a bushing seating surface sized to seat the trailing shoulder of the bushing, a first alignment means attached to said seating surface for axially aligning the bushing sleeve and inner annular member with the longitudinal axis of the bushing installation member, and a second alignment means for engaging the shift cable end protective member and axially aligning the bushing installation member with the shift cable end protective member.
 19. An apparatus as in claim 15, wherein said force-averaging means is comprised of a bushing installation member having a bushing seating surface sized to seat the trailing shoulder of the bushing, a first alignment means comprising an outer alignment member and an inner alignment member centered around the longitudinal axis of the bushing installation member, said outer alignment member extending perpendicularly from the bushing seating surface, said inner alignment member extending perpendicularly from the outer alignment member, and a second alignment means comprising an elongated member centered around the longitudinal axis of the bushing installation member and extending perpendicularly from the inner alignment member, said elongated member sized to engage the shift cable end protective member and axially align the bushing installation member with the shift cable end protective member.
 20. An apparatus as in claim 15, wherein the force-averaging means is comprised of a first cylindrical member having a first side and a second side and a diameter greater than the diameter of the trailing shoulder of the bushing, a second cylindrical member centered around the longitudinal axis of the first cylindrical member, said second cylindrical member having a diameter less than the diameter of the bushing sleeve and greater than the diameter of the inner annular surface and a length less than the distance from the trailing shoulder of the bushing to the inner annular member of the bushing, a third cylindrical member centered around the longitudinal axis of the first cylindrical member and extending from the second cylindrical member, said third cylindrical member having a diameter less than the diameter of the inner annular member of the bushing and a length less than the distance between the inner annular member and the leading shoulder of the bushing, and a fourth cylindrical member centered around the longitudinal axis of the first cylindrical member and extending from the third cylindrical member, said third cylindrical member sized to engage the shift cable end protective member and axially align the first cylindrical member with the shift cable end protective member.
 21. An apparatus as in claim 15 made of a copolymer.
 22. An apparatus as in claim 15 made of acrylonitrile-butadiene-styrene.
 23. A method for installing a bushing into a transmission shift cable end, said shift cable end having a connecting member that connects the shift cable end to the shift cable, a coupling aperture extending through the shift cable end for coupling with the shift lever or gear lever, a semi-spherical member extending longitudinally from its rear surface, said semi-spherical member including a concentric aperture forming a spherical cap, a mounting aperture carried in the coupling aperture, said mounting aperture having a first sidewall and a second sidewall, said bushing having a sleeve dimensioned to fit inside the mounting aperture carrying an inner annular member and having a leading and trailing shoulder for engaging each sidewall of the mounting aperture, said method comprising: providing a shift cable end protective tool having a securing means for securing on to one end of the shift cable end, said securing means including a gripping means for gripping onto the shift cable end connecting member, a force-diverting means for diverting the force applied by any compression tool away from the semi-spherical member and to the rear surface of the shift cable end, and an alignment means for aligning the shift cable end protective tool with a bushing installation tool; securing the shift cable end protective tool over the semi-spherical member and the rear surface of the shift cable end, such that the gripping means engages the shift cable end connecting member; providing a bushing installation tool having a force-averaging means for averaging the force applied by a compression tool across the trailing shoulder of the bushing, and a bushing alignment means for axially aligning the bushing with the longitudinal axis of the coupling aperture during installation; inserting the bushing installation tool into the bushing such that the bushing installation tool engages the sleeve and trailing shoulder of the bushing and aligns the bushing along the longitudinal axis of the bushing installation tool; inserting the bushing installation tool into the shift cable end coupling aperture and mounting aperture, and into to the shift cable end protective tool; applying a sufficient compressive force to the shift cable end protective tool and bushing installation tool such that the leading shoulder of the bushing is compressed to fit through the mounting aperture, the leading shoulder of the bushing passes through the mounting aperture, and expands to engage the second sidewall of the mounting aperture; wherein the shift cable end protective tool diverts the compressive force away from the semi-spherical member and to the rear surface of the shift cable end to prevent damaging the semi-spherical member, and the bushing installation tool averages the compressive force across the trailing shoulder of the bushing to prevent damaging the bushing, and the bushing installation tool engages the alignment means of the shift cable end protective tool to align the bushing with the longitudinal axis of the coupling aperture; removing the shift cable end protective tool and bushing installation tool after the trailing shoulder engages the first sidewall of the mounting aperture and the leading shoulder of the bushing passes through the mounting aperture and expands to engage the second sidewall of the mounting aperture.
 24. A method as in claim 23, comprising: providing a shift cable end protective tool having a shift cable end seating member, said seating member having a first side and a second side, a peripheral surface extending longitudinally from the first side of the seating member, said peripheral surface carrying a gripping means for gripping onto the shift cable end connecting member, said gripping means comprising an opening sized to grasp the shift cable end connecting member, a force diverting means, said force-diverting means comprising a cavity within the first side of the seating member, said cavity sized to fit the semi-spherical member, an alignment means, said alignment means comprising an alignment sleeve centered around the longitudinal axis of the cavity within the first side of the seating member, said alignment sleeve extending to the second side of the seating member, said alignment sleeve carrying a guiding surface for guiding a bushing installation tool into the alignment sleeve during installation; providing a bushing installation tool having a bushing seating member for engaging the trailing shoulder of the bushing and averaging a compressive force across the trailing shoulder of the bushing, a bushing alignment means for aligning the bushing with the longitudinal axis of the bushing installation tool, said alignment means comprising a series of elongated alignment members extending perpendicularly from and centered longitudinally with the bushing seating surface, said elongated alignment members engaging the sleeve and inner annular member of the bushing to align the bushing with the bushing installation tool, and a shift cable end protective tool engagement means for engaging the alignment sleeve of the shift cable end protective tool, said engagement means comprising an elongated engagement member attached to and extending perpendicularly from the alignment means; securing the shift cable end protective tool to the shift cable end such that the cylindrical peripheral surface encompasses the shift cable end, the first side of the seating member engages the rear surface of the shift cable end, the semi-spherical member is housed within the cavity within the first side of the seating member, and the opening in the peripheral surface engages the shift cable end connecting member; inserting the bushing installation tool into the bushing such that the shift cable end protective tool engagement member passes through the bushing, the elongated alignment members engage the sleeve and inner annular member of the bushing, and the bushing seating surface engages the trailing shoulder of the bushing; inserting the bushing installation tool into the shift cable end coupling aperture such that the shift cable end protective tool engagement member passes through the mounting aperture and engages the shift cable end protective tool alignment sleeve; applying a compressive force to the shift cable end seating member and the bushing seating member such that the leading shoulder of the bushing is compressed, inserted through the mounting aperture, and allowed to expand to engage the second side of the mounting aperture; removing the shift cable end protective tool from the bushing installation tool and shift cable end; removing the bushing installation tool from the bushing.
 25. A method as in claim 23, comprising: using a shift cable end protective tool having a cylindrical shift cable end seating member, a cylindrical peripheral surface of a diameter greater than the outer diameter of the shift cable end extending longitudinally from said cylindrical seating member, said cylindrical peripheral surface carrying a semi-circular opening of a diameter marginally greater than the diameter of the shift cable end connecting member, an annular cavity within the first side of the seating member, said annular cavity of a diameter greater than the diameter of the semi-spherical member and of a depth greater than the distance between the rear surface of the shift cable end and the concentric aperture carried by the semi-spherical member, an alignment sleeve centered around the longitudinal axis of the annular cavity, said alignment sleeve having an outer diameter less than the diameter of the concentric aperture and an inner diameter sized to fit the engagement means of the bushing installation tool, said alignment sleeve extending to the second side of the shift cable end seating member.
 26. A method as in claim 23, comprising; Using a bushing installation tool having a cylindrical bushing seating member of a diameter less than the diameter of the shift cable end coupling aperture and greater than the diameter of the trailing shoulder of the bushing, an outer alignment member extending perpendicularly from the bushing seating member, said outer alignment member comprising a cylinder centered around the longitudinal axis of the seating member of a diameter less than the inner diameter of the bushing sleeve and height less than the distance between the trailing shoulder and inner annular member of the bushing, an inner alignment member extending perpendicularly from the outer alignment member, said inner alignment member comprising a cylinder centered around the longitudinal axis of the seating member and of a diameter less than the diameter of the inner annular member of the bushing, an engagement member comprising a cylinder centered around the longitudinal axis of the seating member and of a diameter less than the inner diameter of the shift cable end protective tool alignment sleeve. 